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1.
This paper outlines a plate tectonic model for the Oligo-Miocene evolution of the western Mediterranean which incorporates recent data from several tectonic domains (Corsica, Sardinia, the Kabylies, Balearic promontory, Iberia, Algero-Provençal Basin and Tunisian Atlas). Following late Mesozoic anticlockwise rotation of the Iberian peninsula (including the Balearic promontory and Sardinia), late Eocene collision occurred between the Kabylies and Balearic promontory forming a NE-trending suture with NW-tectonic polarity. As a result of continued convergence between the African and European plates, a polarity flip occurred and a southward-facing trench formed south of the Kabylie—Balearic promontory suture. During late Oligocene time an E-W-trending arc and marginal basin developed behind the southward-facing trench in the area of the present-day Gulf of Lion. Opening of this basin moved the Corsica—Sardinia—Calabria—Petit Kabylie—Menorca plate southward, relative to the African plate. Early Miocene back-arc spreading in the area between the Balearic promontory and Grand Kabylie emplaced the latter in northern Algeria and formed the South Balearic Basin. Coeval with early Miocene back-arc basin development, the N-S-extension in the Gulf of Lion marginal basin changed to a more NW-SE direction causing short-lived extension in the area of the present-day Valencia trough and a 30° anticlockwise rotation of the Corsica-Sardinia-Calabria—Petit Kabylie plate away from the European plate. Early—middle Miocene deformation along the western Italian and northeastern African continental margins resulted from this rotation. During the early late Miocene (Tortonian), spreading within a sphenochasm to the southwest of Sardinia resulted in the emplacement of Petit Kabylie in northeastern Algeria. 相似文献
2.
N–S to NW–SE-trending faults and reverse faults occur within the Palaeozoic Ahnet–Mouydir Basin of the Algerian Saharan Platform, located to the east of the West African Pan-African suture zone. Deformation and stratigraphic analysis show that this basin underwent a NNE–SSW to ENE–WSW shortening at about the Carboniferous/Permian transition or, more probably, during the Early Permian. A brief review of the more or less synchronous deformations registered in the neighbouring regions, and more specifically around the West African Craton, illustrates the mechanical coupling between intraplate tectonics and the Hercynian plate margins orogenies. 相似文献
3.
The Tertiary deformation of the Iberian plate is here interpreted as the result of changes in the coupling between the Iberian–African plates. During the early stages of the Africa/Iberia subduction (Palaeocene), deformation was confined at the Betic plate boundary. From the Eocene, during the collision in the southern plate margin, compressional deformation delocalized and distributed throughout the Iberian plate. First, in the Pyrenees, where the main stage of thrusting occurred during the Late Eocene – Early Oligocene. Then (mainly Oligocene – Late Miocene), in the inner part of the Iberian plate, forming basement uplifts in the Iberian Chain and the Central System, in correspondence of pre-existing (Mesozoic and Variscan) structures. Finally, during the decay of compression inside the Iberian plate, extension took place the Mediterranean margin and the Alboran Sea. 相似文献
4.
Geotectonics - The Gulf of Aqaba is situated along the southern part of the Dead Sea Rift Area transform (DST), 1000 km (620 miles), the boundary between the African plate and the Arabian plate. It... 相似文献
5.
Lateral flow of African mantle below the nearby Tyrrhenian plate: geochemical evidence 总被引:1,自引:0,他引:1
The Quaternary magmatism of the Southern Tyrrhenian basin represents a rare example of an active volcanic arc system where ocean island basalt (OIB) and island arc basalt (IAB) magmas coexist. Although there is general agreement on the importance of the Ionian oceanic lithosphere subduction in the genesis of the IAB magmatism, the tectono‐magmatic processes producing the coexisting OIB magmas are still poorly understood. Here we show that the geochemistry of the Quaternary Southern Tyrrhenian OIB‐type magmatism (i.e. Ustica island and Prometeo, a previously unknown submarine lava field) is very similar to that of OIB‐type volcanoes situated on the nearby African plate (i.e. Etna and Hyblean Plateau). Among the possible geodynamic scenarios proposed to explain the coexistence of OIB and IAB magmas in arc settings, we consider the development of a tear at the edge of the Ionian plate as the more likely mechanism to favour the flow of African asthenospheric mantle below the Tyrrhenian plate. 相似文献
6.
L.E. Ricou J. Dercourt J. Geyssant C. Grandjacquet C. Lepvrier B. Biju-Duval 《Tectonophysics》1986,123(1-4)
The geological data on the Mediterranean chains and basins are used to point out the constraints that they put on the location through time of oceanic versus continental lithosphere and on the successive relations between them. Emphasis is put on the rules and conventions which enable us to interpret the geological data in terms of plate tectonics and on the major disputed points for which a solution must be chosen.In the first part, the location of oceanic versus continental lithosphere is dealt with, using the data on the present-day basins, the ophiolites and the subduction processes. A Neogene age is retained for the Western Mediterranean and the surrounding continental blocks are considered to have been previously a part of Iberia. A Cretaceous age is retained for the Eastern Mediterranean; Apulia is considered as a part of the African plate except for this period. The Black Sea is considered as a back-arc basin formed mostly during the Upper Cretaceous. The ophiolites are used to locate the Mesozoic oceans; for the double ophiolitic belts of the Dinaro-Hellenides and the Taurides, the tectonic interpretations which minimise the number of oceanic basins have been retained. For the Kirsehir block of Turkey, the chosen solution locates a Jurassic ocean to the north and makes it disappear when a Cretaceous ocean opens to the south. Data on the subduction processes added to the information on these basins and led us to consider as oceanic the unknown basements of the Carpathian flysch and the Maghrebian flysch basins.The second part deals with the organisation of basins and platforms, emphasising the chronology of their formation and subsequent crushing. It furnished step by step constraints on the tectonic history of the system which is related to plate displacement.The general pattern derived from these data shows a wedge-shaped Tethyan ocean which disappeared mostly through repeated subduction below the eastern part of its northern margin. The Jurassic stage shows westward extension of the ocean between the Eurasian and African plates and ends with the Dinaro-Hellenic obduction; the Cretaceous stage shows a complete reorganisation including individual displacement of the Iberian, Apulian and Kirsehir sub-plates; the Tertiary stage shows the general collision between the renewed Eurasian and African plates and Neogene subduction of the basins which avoided collision. 相似文献
7.
南大西洋裂解造成的非洲和南美洲的大陆分离到了广泛认可,该区域也与大陆漂移学说的诞生密切相关。但大陆漂移的驱动力从其提出至今一直存在争议,定量化分析大西洋裂解过程中板块运动的驱动力显得尤为重要。我们研究了南大西洋两侧被动大陆边缘盆地区域的两条深反射地震勘探剖面,在构造地质解译基础上,详细估算了非洲大陆的莫霍面倾角,得到了沿莫霍面地壳重力滑移剪切力的大小,用于解释大西洋裂解过程中非洲大陆运动的动力机制。结果说明,非洲大陆板块在地幔上涌形成的倾斜界面上能够产生强大的重力滑移力,且南部驱动力大于中部。大陆板块依靠连续的地幔热上涌和重力滑移力会持续漂移。该模型能够合理解释大西洋上诸多线状分布的大陆残片的成因机制,也能合理解释南大西洋南部宽度大于中部的内在原因,最后对南大西洋的打开过程进行了精细的构造演化史恢复。该研究为板块运动提供了一个新的动力模式,为认识板块运动驱动力提供了更为精确的约束信息。 相似文献
8.
9.
Basic magmatism and geotectonic evolution of the Pan African belt in central Africa: Evidence from the Katangan and West Congolian segments 总被引:1,自引:0,他引:1
In the West Congolian and Katangan Pan African belts, late Proterozoic extensional tectonics related to the relaxation phase that followed the Kibaran collision ca. 1000 Ma ago evolved to reach a mature rift stage characterized by the E-MORB from Kimbungu (Bas-Zaire) in the Pan African West Congolian belt and Kibambale (Shaba, Zaire) in the Pan African Katangan belt.
These mature rifts (proto-oceans) closed during the Pan African orogenic event, in an embryonic collision between the Kalahari craton to the south and the Congo craton to the north. This embryonic collisional belt differs from the classical ones in the lack of subduction and collision magmatic associations. This difference is attributed to the limited extent of the collision (slight crustal thickning) and, notably, to the fact that it happened before the underthrust plate reached the minimum depth required to generate calc-alkaline magmas through subduction. 相似文献
10.
Ferran Estrada Jesús Galindo‐Zaldívar Juan Tomás Vázquez Gemma Ercilla Elia D'Acremont Belén Alonso Christian Gorini 《地学学报》2018,30(1):24-33
The Alboran Sea constitutes a Neogene–Quaternary basin of the Betic–Rif Cordillera, which has been deformed since the Late Miocene during the collision between the Eurasian and African plates in the westernmost Mediterranean. NNE–SSW sinistral and WNW–ESE dextral conjugate fault sets forming a 75° angle surround a rigid basement spur of the African plate, and are the origin of most of the shallow seismicity of the central Alboran Sea. Northward, the faults decrease their transcurrent slip, becoming normal close to the tip point, while NNW–SSE normal and sparse ENE–WSW reverse to transcurrent faults are developed. The uplifting of the Alboran Ridge ENE–WSW antiform above a detachment level was favoured by the crustal layering. Despite the recent anticlockwise rotation of the Eurasian–African convergence trend in the westernmost Mediterranean, these recent deformations—consistent with indenter tectonics characterised by a N164°E trend of maximum compression—entail the highest seismic hazard of the Alboran Sea. 相似文献
11.
The geometry and geochronology of aseismic ridges and oceanic islands in the southern oceans provide a good test of the proposition that hotspots remain fixed over long periods of time; that is, motion of an order of magnitude less than the relative motion between plate pairs. In most cases it is concluded that inter-hotspot movement cannot be discerned for the period 100 m.y. to Present and that widely distributed hotspots in the Atlantic and Indian Oceans provide a frame of reference for plate motions following the disintegration of Gondwanaland, which is independent of paleomagnetism. This frame of reference is “absolute” in that it gives the motion of the lithosphere with respect to the mantle (= hotspots). The absolute motion model indicates that Africa and Antarctica are now moving only very slowly, that there has been significant relative movement between East and West Antarctica since the Cretaceous, and prescribes the relative motion between the Somali and African plates. 相似文献
12.
New seismicity and focal-mechanism data from the area of the Azores Islands, in the Mid-Atlantic Ridge, to the Alboran Sea and the southern part of Spain are presented.As a consequence of the different characters in the focal-mechanism solutions and b-values associated, the area has been divided in four different parts, namely, Mid-Atlantic and Terceira Ridge, Azores—Gibraltar fault, Gulf of Cadiz, Alboran Sea and Betica. The last two form the interaction between the Eurasian and African continental plates.The fracture zone is the locus of very large earthquakes with mechanisms showing a predominant right-lateral horizontal motion. Seismic foci in the continental interaction zone are spread over the whole region with mechanisms changing in character from west to east. It is suggested that this may be consequence of the behaviour of the Spanish Peninsula as a partly independent subplate. In the eastern part of the studied zone, the so-called Alboran plate may be considered as a buffer plate. 相似文献
13.
We constrain the multistage tectonic evolution of the Palaeoproterozoic UHT metamorphic(P=0.9–1.0 GPa,T>1000℃,t=2088–2031 Ma)Bakhuis Granulite Belt(BGB)in Surinam on the Guiana Shield,using large-to small-scale structures,Al-in-hornblende thermobarometry and published fluid inclusion and zircon geochronological data.The BGB forms a narrow,NE–SW striking belt between two formerly connected,~E–W oriented granite-greenstone belts,formed between converging Amazonian and West African continental masses prior to collision and Transamazonian orogeny.Inherited detrital zircon in BGB metasediments conforms agewise to Birimian zircon of West Africa and suggests derivation from the subsequently subducted African passive margin.Ultrahigh-temperature metamorphism may have followed slab break-off and asthenospheric heat advection.Peak metamorphic structures result from layer-parallel shearing and folding,reflecting initial transtensional exhumation of the subducted African margin after slab break-off.A second HT event involves intrusion,at ca.0.49 GPa,of charnockites and metagabbros at 1993–1984 Ma and a layered anorthosite at 1980 Ma,after the BGB had already cooled to<400℃.The event is related to northward subduction under the greenstone belts,along a new active margin to their south.A pronounced syntaxial bend in the new margin points northward towards the BGB and is likely the result of indentation by an anticlinorial flexural bulge of the subducting plate.Tearing of the subducting oceanic plate along this bulge explains why the charnockites are restricted to the BGB.The BGB subsequently experienced doming under an extensional detachment exposed in its southwestern border zone.Exhumation was focused in the BGB as a result of the flexural bulge in the subducting plate and localised heating of the overriding plate by charnockite magmatism.The present,straight NE–SW long-side boundaries of the BGB are superimposed mylonite zones,overprinted by pseudotachylites,previously dated at ca.1200 Ma and 950 Ma,respectively.The 1200 Ma mylonites reflect transpressional popping-up of the BGB,caused by EW-directed intraplate principal compressive stresses from Grenvillian collision preserved under the eastern Andes.Further exhumation of the BGB involved the 950 Ma pseudotachylite decorated faulting,and Phanerozoic faulting along reactivated Meso-and Neoproterozoic lineaments. 相似文献
14.
N. J. Skinner 《Tectonophysics》1979,53(1-2)
A negative anomaly in the vertical magnetic field component at a site in Nigeria has recently been interpreted by Oni in terms of a possible north-south shift of the western sector of the African plate. In this paper, comments are made under the headings of magnetic field reversals, polar wander and secular variation, which cast doubt on Oni's interpretation. 相似文献
15.
Preliminary results from a few Triassic, Jurassic and Cretaceous rocks indicate that Israel has behaved as part of the African plate during this period. Earlier palaeomagnetic results from the Lebanon, previously explained in terms of a separate Levantine plate, can be better explained in terms of differential motion between fault blocks in response to motions along the Dead Sea Fault. The available evidence allows determination of the net motions of specific fault blocks and is consistent with independent palaeogeographic indicators of the pretectonic relationship between these blocks. 相似文献
16.
The core of the Troodos Massif consists of a major tectonitic harzburgite—dunite unit (Mt. Olympus Unit) overlain by three tectonic units which, in descending order, consist of dunites, wherlites and gabbros, respectively. Furthermore, the Mt. Olympus Unit is underlain by three other tectonic units with the same lithology as the upper ones. The thrusts show a north-to-south emplacement, probably of latest Cretaceous age.It is suggested that Troodos, Southern Turkey, Hatay and Oman ophiolites could belong to the same oceanic domain; they underwent different displacement toward the Arabian—African plate. 相似文献
17.
Abdessalem El Ghali Noureddine Ben Ayed Claude Bobier Fouad Zargouni Anis Krima 《Comptes Rendus Geoscience》2003,335(9):763-771
In central Tunisia, a synsedimentary tectonic episode has been pointed out through the tectonic movements affecting the Late Palaeocene–Early Eocene successions. This tectonic episode has controlled, to a large extent, the palaeogeographic setting of the area during that period and confirmed the important effect induced by the Pyrenean shortening phase on the edge of the African plate, which obviously has witnessed a common history with the southern part of the European plate. To cite this article: A. El Ghali et al., C. R. Geoscience 335 (2003). 相似文献
18.
The Mesozoic apparent polar wandering (APW) of the Transdanubian Central Mountains, determined from thermally isolated natural remanences at 13 localities, shows a remarkable similarity to the Mesozoic APW of Africa in that they both exhibit the same loop-like movement. Moreover, the difference between the two APW's can practically be eliminated by a 35° clockwise rotation of the palaeodeclinations. It is concluded, therefore, that the region of the Transdanubian Central Mountains was part of the African (-Adriatic) plate up to some time in the Cenozoic when it moved to its present position, resulting in a 35° anticlockwise rotation relative to Africa. 相似文献
19.
20.
Paleopositions of the African, Indian and Antarctic plates are used as an independant set of data to test various hypotheses, derived from geophysical data, on the origin, emplacement mechanism and evolution of five aseismic structures of the Western and Southern Indian Ocean (Crozet and Kerguelen plateaus, Marion Dufresne, Léna and Ob seamount chain, Madagascar and Mascarene ridges).Except for a continental fragment of very limited extent bearing the Seychelles Islands, these structures, together with the Madagascar and Mascarene ridges, are probably due to anomalous volcanic episodes at —or near— active plate boundaries, rather than to intraplate emplacement. Their creation processes are therefore mainly related to the relative motions between the Antarctic, African and Indian plates. The volcanic episodes are synchronous with major changes in the relative motions between these plates and thus substantiate the role played by frequent irregularities in the kinematic pattern of the Western and Southern Indian Ocean, such as ridge jumps, asymmetric spreading and rapid variations in spreading velocity or direction. Finally, we think that thermal anomalies, located not far from active spreading boundaries, may have played a role in the physical processes creating the aseismic ridges. 相似文献